Procedure for the preparation and performing of a post issuance process on a secure element

ABSTRACT

A method for enabling post issuance operation on a secure element connectable to a communication device is disclosed. The method allows an SE controlling party to perform remotely operations such as creation of new security domains for an external party, loading, and installation of applications of an external party and management functions including personalization and activation of applications loaded on the SE for an external party. The method includes the steps of:
         collecting data stored on the SE suitable for identification of the SE and data for contacting the SE controlling party;   creating an initial data packet from the collected data,   sending the data packet to a party which can be the external party, an agent of the external party, the SE controlling party, an agent of the SE controlling party.       

     A communication device and a software application for implementing the method are also disclosed.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation-in-part of PCT/HU2008/000114 filed on 6 Oct. 2008 and claims priority of Hungarian Patent Application No. P0700685 filed on 20 Oct. 2007.

FIELD OF INVENTION

The present invention relates to a method for enabling post issuance operation on a secure element (SE) connectable to a communication device by a party controlling the SE. In a first aspect of the invention the method is performed by the communication device or a software application running on the communication device. In a second aspect the method is performed by an external party such as a service provider.

The invention further relates to a communication device which is connectable to a secure element and a software application that can be installed on such a communication device.

In the context of the present invention the terms “secure element” or “SE” mean a secure storage part-unit, such as a chip card, e.g. the SIM cards used in mobile handsets, or a smart card inserted into a PC, or terminal as well as a special software application as part of the operating system of the device.

BACKGROUND OF INVENTION

As a result of the development of communication devices, and secure elements especially in mobile telephone sets, handheld computers as well as chip-cards, an increasing number and wide range of services have become available for users on the new generation of communication devices. Some of the available services are pre-installed on the communication device or on the secure element in it, but information contents realizing other services also exist which, may need to be or are preferably downloaded later on to the user's communication device based on the choice of the user. Frequently due to security considerations, sensitive information content or part of the information content should preferably be downloaded onto the secure element of the communication device, i.e. to a protected storage unit.

However, according to the present state of the art in general the entire storage area of the secure element suitable for receiving such information content is linked to a single entity, to the secure element issuer (SE issuer) itself, and is essentially exclusively used by this entity. This circumstance is disadvantageous for both the service providers wishing to offer new services via new applications and for the users of the communication devices. The current situation also prevents the SE issuer to economically utilize the available capacity of the secure element. In most cases the capacity and potentials of the secure element are not exploited to their full extent. The secure element placed in the communication device includes, in general, a unified storage area, or even if part areas separated from each other exist, they are not utilized by multiple services, service providers or applications. The secure elements are pre-personalized and personalized quasi during the chip-card manufacturing process, and after this is completed neither the secure element issuer who in most cases is also the service provider nor the user is able to reconfigure the content of the secure element. This practice may cause much of the card capacity, and certain storage part areas to be unused, as at the time of production, or before the issuance of the secure element it is not possible to know the real commercial demands relating to the existing and future services. Hence, some unnecessary applications may be pre-loaded and pre-installed on the card, while other services that would actually be required by the users may be left out.

US 2002/053090 discloses a data receiving apparatus having a storage unit wherein an exclusive memory area can be secured for a service provider, such as a broadcasting provider. However, the exclusive memory area is secured (or deleted) by a program operating on the data receiving apparatus. Because the exclusive memory area is managed locally and there is no external controlling/managing party, the exclusive memory area is more prone to tampering, which renders it unsuitable for use in combination with services where high security is required. Also if the storage capacity management is performed off-line without the involvement of the secure element issuer/owner there is no possibility for the commercialization of the available storage space, the financial incentives are missing.

SUMMARY OF INVENTION

The objective of the present invention avoids the unfavorable pre-installation practice during the traditional issuance process of the secure elements, and to enable dynamic post issuance operations (procedures), even between previously unknown parties in an ad-hoc manner, utilizing the potential provided by mobile or stationary (terminal) communication devices. Such post issuance operations are understood to comprise creation of new security domains (uniquely accessible storage areas), loading and installation of applications as well as other types of management functions, such as personalization and activation of the applications loaded on the secure element.

More specifically it is an object of the invention to allow for the dynamic creation of security domains serving to receive various information content, and to also allow for the deployment of information and applications belonging the various service providers onto the secure element after the card has been manufactured and put into distribution, and in such a way that selected information stored on the secure element, and collected by the communication device, or an application running on the communication device the secure element is attached to, is used for the facilitation of the overall remote post issuance procedure, by sending this information by the communication device to either the owner-issuer (the service provider or its supporting party) of the application/data that needs to be loaded onto the secure element, or directly to the controlling party of the secure element and letting them process this information according to the methodology described. The recognition that led to the procedure according to the invention was that if some type of secure element identification and the direct or indirect (e.g. searchable in a database) contact information of the SE controlling party (SE issuer or its agent, service manager) is provided in a determined data group of the secure element, and this data is queried by the communication device or an application running on it, then by sending this information, and also potentially other data elements related to the secure element, the communication device and/or running environment and/or user and/or content, to the owner-issuer of the application, which needs to be loaded onto the secure element, or directly to the controlling party of the secure element the dynamic post issuance operations (such as setting up of security domains and authorizing access to the security domain for a determined party, e.g. service provider, or the loading, personalization and activation of the application) can be realized on the secure element even after the pre-personalization and initial personalization of the chip card (secure element) and its delivery to the user.

The inventors have also realized that with the unique utilization of suitably selected data elements stored on the secure element and by creating data packets therefrom and forwarding the data packets by the communication device in accordance with the procedure of the invention it is possible to effect the post issuance operations on a secure element over the air, i.e. via a remote communication connection in such a way that even previously unknown parties—secure element controllers, and service providers—can start working together to realize the post issuance procedure on the user's secure element and can load remotely the required application onto the secure element.

Over the air (OTA) techniques are readily available as well as providers allowing for performing post issuance (including personalization) procedures remotely. OTA is a service but it is also a common name for various known communication technologies that enable secure data transfer between an SE and a back-office architecture. From the perspective of the present invention the technical implementation of OTA services is transparent and does not affect the main concept of the invention.

In accordance with the above objectives the invention provides a procedure for enabling post issuance operation on a secure element connectable to a communication device by a controlling party of the secure element. The procedure or method comprises the steps of:

-   -   collecting from the secure element data suitable for the         identification of the secure element and data for contacting the         secure element controlling party;     -   creating an initial data packet from the collected data, and     -   sending the data packet to a party selected from a group         consisting of an external party, an agent of the external party,         and the secure element controlling party.

In this aspect of the invention the communication device, or a software application running on the communication device, performs the procedure that enables the post issuance operation. The post issuance operation is carried out on the secure element remotely by the SE controlling party. This may include the creation of new security domains for an external party, loading, and installation of applications of an external party and management functions including personalization and activation of applications loaded on the secure element for an external party.

The invention further relates to a procedure for preparing post issuance operation on a secure element connected to a communication device which comprises the steps of:

-   -   receiving an initial data packet sent by the communication         device to which the secure element is connected, the data packet         comprising data suitable for the identification of the secure         element and data for contacting the SE controlling party,     -   processing the initial data packet received from the         communication device, including determining the contact         information of the SE controlling party of the secure element         from the initial data packet,     -   creating from the initial data packet a position request data         packet comprising data suitable for the identification of the         secure element and the requested information, and     -   sending the position request data packet to the address defined         by the contact data of the SE controlling party.

In this aspect of the invention the procedure for enabling the post issuance operation is performed by an external party such as a service provider. The post issuance operation is carried out on the secure element remotely by the SE controlling party, this may include the creation of new security domains for an external party, loading, and installation of applications of an external party and management functions including personalization and activation of applications loaded on the secure element for an external party.

The invention further relates to a communication device for reading a secure element, the communication device being programmed to:

-   -   collect data stored on the secure element comprising data         suitable for the identification of the secure element and data         for contacting an SE controlling party of the secure element,     -   create a data packet comprising at least the data suitable for         the identification of the secure element and data for contacting         the SE controlling party, and     -   send the data packet to an addressee chosen from a group         consisting of an external party, an agent of the external party         and the SE controlling party.

The invention further relates to a software application configured for installation on a communication device connectable to a secure element, the software application being adapted for:

-   -   collecting data suitable for the identification of the secure         element and data for contacting an SE controlling party from the         secure element,     -   creating a data packet comprising at least the data suitable for         the identification of the secure element and data for contacting         the SE controlling party, and     -   sending the data packet to an addressee chosen from the group         consisting of an external party, an agent of the external party,         and the SE controlling party.

Sending the data packet is understood to include the possibility of forwarding the data packet to a further program installed on the communication device and/or to a hardware device which is responsible for the transmission of the data packet. Moreover, any number of hardware and related software as well as further parties may participate in carrying out the actual transmission.

Further advantageous embodiments of the invention are defined in the attached dependent claims.

The objective was further more to elaborate a procedure for the service providers which ensures that the information received from the communication device that is connected to the secure element can be used to initiate communication with the controlling party of the secure element and the establishment of the new security domain, or the loading of the application can be requested in an ad hoc manner in a quasi real time procedure. One of the most important advantages of the procedures according to the invention is to provide a possibility to subsequently reconfigure the application portfolio stored on the secure element remotely and even repeatedly whereby even independent security domains (storage areas) may be created and applications may be loaded in such a way that the required data exchange between partners that are unknown to one another becomes possible in a simple automated manner.

An advantage deriving from this is that an entire secure element becomes usable by completely independent content service providers, and the information content—even without the direct physical connection between the participants—is in all cases downloadable to a security domain that is uniquely accessible, i.e. inaccessible to other parties. Thus the use of the secure element can be optimized allowing the user to access and use several different applications even new applications available only after the original issuance of the secure element and applications can also be stored on the secure element even temporarily for a limited period of time, only as long as they are needed.

It is important to see that post issuance personalization of a secure element has already been possible even prior the present invention based on various Global Platform specifications. But all these specifications are missing the points of how to initiate the post issuance procedure between previously unknown parties in such a way that can lead to a convenient, automated procedure. The present invention solves this problem, because it identifies certain data elements to be placed on the secure element, and a communication device to collect and communicate this information and a processing methodology of the communicated information which combined makes it possible to establish the initial communication between even previously unknown parties, a secure element issuer and a service provider, that can lead to the successful realization of a fully automated post issuance procedure on a secure element attached to a communication device.

BRIEF DESCRIPTION OF THE DRAWINGS

In the following the set of equipment used for the procedure according to the invention is presented in more detail on the basis of exemplary embodiments and drawings. In the drawings,

FIG. 1 shows the block diagram of a possible embodiment of the set of equipment used during the procedure.

FIG. 2 shows the block diagram of the participating parties of an exemplary embodiment of the procedure according to the invention.

FIG. 3 is a block diagram of an advantageous embodiment of the inventive procedure.

FIG. 4 is a block diagram of another advantageous embodiment of the inventive procedure.

FIG. 5 is a schematic diagram of another advantageous embodiment of the inventive procedure.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

FIG. 1 schematically depicts a possible set of devices with the help of which the procedure according to the invention may be realized. A user 8 may be equipped with various types of communication devices 10 of which two exemplary embodiments can be seen, one of them being a mobile telephone set (handset), while the other one is a portable mini-computer. However, the term communication device should be interpreted in a broad sense; any apparatus suitable for performing the essential functions of the exemplified embodiment of the communication device 10 disclosed in the present specification is understood to be a communication device in accordance with the invention. For example any card terminal is also included that is capable of performing the functions required of the communication device according to the invention, e.g.: reading specific information from the secure element, creating data packets including the captured information and sending the data packets to specified addresses using any type of communication channel.

The individual communication devices 10 may be connected to external parties, which are in the present example a service provider 30 and/or its agent 30 a (see FIG. 2), as well as being connected to a SE controlling party 50 by an information forwarding network 70 (such as the Internet or a mobile communication network). In the context of the present invention the external party is the party for whom a new security domain is created, or whose application or data is loaded, or installed on the SE, or on the behalf of whom other management functions, such as personalization and activation of applications loaded on the secure element is performed.

The SE controlling party may be an SE issuer 50 a and/or its agent 50 b, (e.g. a Trusted Service Manager) assisting the interactions of the SE issuer 50 and other parties to perform such activities that in the traditional pre-personalized, static, single application environment would not be necessary and therefore the SE issuer may not be capable of. These tasks are related to the post issuance, multi application management functions like the approval of loading request, allocation of card storage capacity and the initiation and realization of the actual application installation process, including the necessary administrative and security procedures like key management. For the sake of simplicity, when distinction is not important, we will call both the SE issuer 50 a and its agent 50 b universally the SE controlling party. The SE controlling party term also includes the entity who manages a specific subdomain of the card independently of the SE issuer. This entity performs in practice the same or similar processes as the SE issuer does on a traditional Global Platform card.

The service provider 30 and the SE controlling party 50 are understood to include the information technology infrastructure required for performing the various steps of the procedure according to the invention. Such infrastructure typically includes computer servers.

A plurality of other entities may also be involved in the interactions of the communication device 10 of the user 8, the service provider 30 and the SE controlling party 50 as illustrated in FIG. 2, such as one or more OTA providers 100 providing OTA (over the air) services, or one or more trusted service managers (TSM) 110, i.e. a trusted third party, who can provide the technology and service support necessary for realizing certain new types of services, for which service providers 30 and/or users 8 may not be technically ready. For example the service provider's agent 30 a can be a TSM 110 that may perform the remote application management for the service provider 30 while the user's TSM 110 may provide certain types of customer support functions for the user. Both the user 8 and the service provider 30 may employ a separate TSM 110 or the same TSM 110 may be acting for the different parties. It is also possible that the secure element issuer's 50 a agent 50 b is a TSM (being the actual SE controlling party 50) is the same entity which provides technical support for the service provider 30 as well as for the users 8.

As an alternative to the information forwarding network 70 the service provider 30 may be provided with a special interface 90 via which it is possible to directly communicate with communication device 10. For example the communication device 10 may be an NFC-enabled (near field communication enabled) mobile handset capable of communication with an NFC interface 90.

The exemplary mobile telephone set serving as the communication device 10 comprises a central unit 11, which controls the operation of the communication device 10, and a secure element 20 (typically in the form of some type of a chip card, which can be fixed or removable) which is connected to the central unit 11, and, furthermore, another storage area 12 of the communication device 10. The other storage area 12 comprises a storage register 21, while the secure element 20 contains at least one, but potentially more security domains 22 some of which are to be created according to the present procedure or in which the applications can be loaded into using the present procedure.

An initial data packet 40 is also associated with the communication device 10, which contains SE data 41 stored in the secure element 20 and optionally supplementary data 42 stored in the storage area 12 of the communication device 10. The SE data 41 and the supplementary data 42 are data that may be forwarded either via the information forwarding network 70 or via the interface 90 to the service provider 30 or to the SE controlling party 50.

The SE data 41 comprises data suitable for the identification of the secure element 20 by the SE controlling party 50 in order to be able to carry out post issuance operations on the specific secure element 20. Preferably the SE data 41 also comprises the secure element's 20 CPLC (Card Product Life Cycle, see: e.g. EMV-CPS-1.0 Final) information and/or the Card Recognition Data in order to evaluate the security environment and other details of the secure element 20. The SE data further comprises data for contacting the SE controlling party 50 (e.g. an automated contact information of the SE controlling party 50). The direct contact information of the SE controlling party 50 may contain data such as its information network identifier (e.g. telephone number or IP address) or any other type of unique identification means that can also be processed electronically.

It should be noted that the identification of the SE controlling party 50 need not necessarily be carried out directly. The SE data 41 may contain the indirect contact information of the SE controlling party 50, whereby the SE controlling party 50 is only represented by a so-called “pointer”, which, for example, points to a given element of a remotely accessible computer database, and this element contains the real direct contact details of the SE controlling party 50.

Furthermore, the SE data 41 may also contain character series identifying the registered user of the secure element 20 (e.g. user name).

The supplementary data 42 is preferably stored in the normal storage area 12 of the communication device 10 (e.g. in the telephone memory of a mobile handset) and may include information suitable for the identification and technical description of the communication device 10 (e.g. serial number, telephone number of a mobile handset, etc.) in order to allow the service provider 30 to establish whether the communication device 10 meets the technical requirements of the requested service application and the service provider 30.

In the following the procedures according to the invention are presented in more detail through examples.

Example 1

In this embodiment of the procedure according to the invention the goal was to create a security domain 22 in a secure element 20 of a communication device 20 in order to receive information content (e.g. a ticketing application). The steps of the procedure are schematically illustrated in FIG. 3.

An initial data packet 40 was created in Step 131 (FIG. 3) by the data collecting application installed on the communication device 10. The data packet 40 included the SE data 41 which contained information suitable for the identification of the secure element 20 (e.g. the serial number of the secure element 20) and direct contact information of the SE controlling party 50 (e.g. the secure element issuer). The supplementary data 42 of the data packet 40 contained identification data of the communication device 10 (e.g. type of the device) for identifying the technical capacity of the device 10. The supplementary data 42 preferably includes information identifying the request of the user 8 as to what kind of service application should be installed on the secure element 20 of the communication device 10. Optionally this information may be provided inherently by sending the initial data packet 40 to a specific address corresponding to the distribution of the required service, the ticketing application in the present example.

The function of this initial data packet 40 which is created by a pre-installed data collecting software application (a HOST program) of the communication device 10 is to make it clearly determinable during the inventive procedure in which secure element 20 the security domain 22 is to be created on, or on which secure element 20 should the requested loading/installation/personalization/activation of an application take place, and who or which SE controlling party 50 is able to perform this. The pre-installed software application may be installed by the manufacturer or the user may download it and install it subsequently. The data collecting software application may also be provided by the service provider 30 in which case the address to which the initial data packet 40 is to be sent to may be included in the data collecting application, alternatively the application may be provided by the controlling party 50 of the secure element 20, in which case the application itself may already contain relevant information in respect of the SE controlling party 50 and only the information relevant for the secure element needs to be collected. The data collecting software application dynamically collects all the required data and creates the initial data packet 40. Collecting of the data may be performed automatically each time the communication device 10 is switched on, or only upon launching the data collecting software application. The data collecting software application may obtain data from both the normal storage area 12 of the communication device 10 and the secure element 20.

After the initial data packet 40 had been created using the communication device 10 (and more specifically by the data collecting application), in Step 132 it was sent to the service provider 30 operating a ticketing application through the information forwarding network 70. After receiving the initial data packet 40 at the service provider 30 the SE data 41 and the supplementary data 42 were processed in Step 133, whereby the application corresponding to the request of the user 8, the communication device 10 of the user 8 and the secure element 20 thereof were identified, furthermore, the contact information of the SE controlling party 50 controlling the secure element 20 was also determined.

Following this the service provider's 30 position request data packet 60 was set up by the service provider 30, which included as identification data 61 information content identifying the secure element 20 and the communication device 10 containing the secure element 20, as well as information identifying the service provider 30. and its application. Some or all the data comprised in the identification data 61 may be data extracted from the initial data packet 40 or it may simply be a part of the initial data packet 40 which is forwarded in the position request data packet 60 to the SE controlling party 50 typically through the information forwarding network 70.

In Step 134 the position request data packet 60 was sent to the SE controlling party 50 (the SE issuer 50 a or its agent 50 b) where it was processed in Step 135 in order to identify the necessary data for carrying out the post issuance process. The secure element 20 on which the security domain 22 had to be made as well as the communication device 10 containing it was identified from the position request data 60 and more specifically from the identification data 61. Following this, in Step 136 the required security domain 22 was created by the SE controlling party 50 remotely using OTA technology. This involved sending a group of instructions, according to Global Platform life-cycle management specifications. (See: Global Platform Card Specifications) to the communication device 10 containing the secure element 20 with which the security domain 22 was created.

In Step 137 an access data packet 80 containing the access parameters (e.g. specific keys) authorizing operations on the security domain 22 were created. The access data packet 80 indicates data (group of information) with the use of which the required security domain 22 or uniquely accessible information content loaded on the secure element 20 of the communication device 10 may be accessed. The access data packet 80 is either sent to the service provider 30 directly or it is sent to the communication device 8 from where it is forwarded to the service provider 30. In the present example the access data packet 80 was sent by the SE controlling party 50 to the service provider 30 in Step 138 through the information forwarding network 70. Thus the security domain 22 requested by the service provider 30 and only accessible by the service provider 30 was created in the given secure element 20 of the user's 8 communication device 10.

Example 2

In this embodiment of the procedure according to the invention, as opposed to that presented in the previous example, the contact details of the SE controlling party 50 was determined first by the service provider 30 in Step 133 on the basis of the indirect contact data stored in the secure storage part unit 20 located in the user 8 mobile handset communication device 10.

In order to acquire this data, from the indirect contact information placed in the secure element 20 a determined section of a database was reached from which the direct contact details of the SE issuer appearing as the SE controlling party 50 of the given secure element 20 were acquired. In the possession of this information a position request data packet 60 was created from the SE data 41 suitable for identifying the secure element 20 and from the supplementary data 42 identifying technical properties of the communication device 10, furthermore, from the details of the service provider 30 wishing to install a service application onto the requested security domain 22 and of the service application itself.

In this embodiment the position request data packet 60 was sent via information forwarding network 70 to the SE controlling party 50 in Step 134, where it was processed in Step 135. Following this, a security domain 22 on the secure element 20 of the communication device 10 in Step 136, and in Step 137 an access data packet 80 was created for the service provider 30 allowing unique access to the security domain 22. The service provider 30 was informed of the creation of the security domain 22 over the information forwarding network 70 in Step 138, and at the same time the access data packet 80 was sent to it. Thus a new security domain 22 has been created on the secure element 20 of the communication device 10 suitable for receiving the information content (e.g. service application) offered by the service provider 30.

Example 3

The present embodiment of the inventive procedure (illustrated in FIG. 3 as well) differs from the embodiment described in Example 1 in that the post issuance process involves loading uniquely accessible data content (application) onto the secure element 20, instead of creating a uniquely accessible security domain 22.

The procedure is very similar, in Step 131 an initial data packet 40 is created at the communication device, which is sent to the service provider 30 in Step 132. In Step 133 the service provider 30 processes the initial data packet 40, determines the SE controlling party 50 (either from direct or indirect contact information included in the initial data packet) and creates a position request data packet 60, which comprises certain required data obtained from the initial data packet 40 and information relating to the data content to be loaded on the secure element 20.

The service provider 30 sends the position request data packet 60 to the SE controlling party 50 in Step 134. The data content to be uploaded on the secure element 20 may be sent together with or even as part of the position data request 60, or it may be sent separately possibly upon request from the SE manager.

In Step 135 the data packet 60 is processed by the SE controlling party 50. In the present embodiment of the inventive procedure the SE manager does not create a uniquely accessible security domain 22, instead it uploads the required data content, application on the secure element 20 in Step 136. Optionally personalization operations may be carried out by the SE manager as well. Similarly to the previously described procedures the SE manager creates an access data packet 80 for accessing the uniquely accessible data content uploaded on the secure element 20 (Step 136) and sends this data packet 80 to the service provider (Step 137).

Example 4

In this embodiment of the procedure according to the invention a security domain 22 is created in a post issuance process without the active participation of the service provider 30 (or any other external party destined to have access to the security domain 22).

As illustrated in FIG. 4, in Step 141 a data packet 40 is created at the communication device 10 (possibly with the help of the data collecting application). In the present example the data packet 40 does not only comprise the SE data 41 and supplementary data 42 as described above, but may also comprise data relating to the size and optionally other technical requirements of the security domain 22 to be created in the secure element 20, as well as data identifying an external party (typically the service provider 30) destined to have access to the security domain 22. In step 142 this data packet 40 is sent directly to the SE controlling party 50, where it is processed in Step 143 in a similar manner as described in the above examples in connection with the position request data packet 60.

In Step 144 the uniquely accessible security domain 22 is created and an access data packet 80 is provided in Step 145. In Step 146 the access data packet 80 allowing access to the security domain 22 is sent directly to the designated service provider and/or to the user's communication device 10.

Although the above procedure have been described as a three-party process (in the case of Example 4 as a two-party process) it is clear that further parties may be involved in the interactions of any two main parties (i.e. the user 8, the service provider 30 and the SE controlling party 50). For example OTA service providers 100, certification authorities or TSMs 110 may receive and forward any of the data packets 40, 60, 80 to its destination (i.e. to the user 8, the service provider 30 or the SE controlling party 50).

Example 6

FIG. 5 illustrates a more general exemplary procedure according to the invention wherein further parties such as an OTA provider 100 and a TSM 110 participate as well. In Step 151 of the present example the user 8 sends a service request to the service provider 30 either directly or via the TSM 110 using the communication device 10. After this the service provider sends back an inquiry in Step 152 requesting detailed information about the IT environment (in the present embodiment the communication device 10 is a mobile handset, thus the IT environment corresponds to the mobile environment). A HOST program (e.g. the above described data collecting software application) on the mobile handset 10 performs the information collection in Step 153 and an initial data packet 40 is created based thereon. The handset then transmits back the initial data packet 40 in Step 154 to the service provider 30 or its TSM 110, where the data packet 40 is processed and the information relating to the secure element and the mobile handset 10 is evaluated in Step 155, to see whether the secure element and the handset 10 meets the technical requirements of the offered service (and optionally any other requirements). In the present example the procedure involves looking up the direct contact information of the SE controlling party 50 in a remote database (the SE controlling party database 120) in Step 156 and obtaining the direct contact information of the SE controlling party 50 therefrom in Step 157. After this in Step 158 the service provider 30 creates the position request data packet 60 as explained above, and in Step 159 the positions request data packet 60 is sent to the SE controlling party 50 (possibly via the TSM 110) based on the direct contact information obtained from the SE controlling party database 120. In Step 160 the SE controlling party processes the positions request data packet 60 determining the secure element 20. Thereafter, in Step 161, the SE manager starts the post issuance process via OTA and with the help of the OTA provider 100 in order to create the security domain 22 in the secure element 20. A feedback about the status of the OTA activity is sent back from the secure element 20 to the SE controlling party 50 in Step 162. The SE controlling party 50 then creates an access data packet 80 in Step 163 allowing unique access to the newly created security domain 22. This access data packet 80, serving as a confirmation response and comprising the specific keys to access the security domain 22, is sent to the service provider 30 in Step 164 either directly or via its TSM 110.

Example 7

In this embodiment of the procedure according to the invention the user has a secure element 20 in the form of a plastic chip card having the same capabilities as described in respect of the secure element 20 within the mobile phone. This chip card contains one or more preloaded applications and stores all the relevant information that is necessary to assemble the data packet identifying the secure element itself and its issuer/owner/controlling party. The user places/touches this card into a service terminal operated by a service provider 30 itself or by another third party acting on its behalf. In this scenario the service terminal acts as the communication device 8 being connected either to the service provider or to its agent or directly to a card issuer (an SE issuer). When the user selects the desired functionality of the terminal associated with loading of a new application onto the card, the terminal reads the necessary information from the card—e.g.: its serial number, and the contact information of its controlling party—prepares the initial data packet 40 and forwards this request either to the service provider 30 or to its agent, or directly to the controlling party 50 of the chip card 20. From this point on the process is the same like described in the above detailed examples. If the initial data packet 40 was sent to the service provider or to its agent, it prepares a position request data packet 60 and sends it to the controlling party 50 of the secure element 20. The SE controlling party 50 establishes communication with the terminal and through the terminal with the secure element 20 connected to it and performs the post issuance life-cycle management procedure requested by the service provider. When the process is completed and either a new security domain is established or the application, or simply data is loaded onto the card the SE controlling party 50 sends the access data packet 80 to the service provider 30 which enables the service provider 30 to complete the installation process of the new application. When removing the card 20 from the service terminal the user can use the new application with any applicable card reader device.

The above-described embodiments are intended only as illustrating examples and are not to be considered as limiting the invention. Various modifications will be apparent to a person skilled in the art without departing from the scope of protection determined by the attached claims. 

1. A method for enabling a post issuance operation on a secure element (SE) controlled by a SE controlling party, which element is connectable to a communication device, comprising the steps of: collecting from the SE data suitable for the identification of the SE and data for contacting the SE controlling party; creating an initial data packet from the collected data; and sending the data packet to a party selected from a group consisting of an external party, an agent of the external party, and the SE controlling party.
 2. The method according to claim 1, wherein the external party's agent is a trusted service manager.
 3. The method according to claim 1, wherein the SE controlling party includes SE issuer and SE issuer's agent, and the SE issuer's agent is a trusted service manager.
 4. The method according to claim 1, wherein the step of creating the initial data packet also includes the collection of data stored on the communication device.
 5. The method according to claim 1, wherein the data for contacting the SE controlling party comprises a pointer to a remote database containing direct contact details of the SE controlling party.
 6. The method according to claim 1, wherein the initial data packet further comprises information identifying user of the communication device and the external party.
 7. The method according to claim 1, wherein the initial data packet includes character series identifying the communication device.
 8. The method according to claim 1, wherein the initial data packet includes CPLC data for identification of the SE and an associated SE controlling party.
 9. The method according to claim 1, wherein the contact data of the SE controlling party is stored in an information network identifier located in the secure element.
 10. The method according to claim 1, wherein sending the data packet is performed over an information forwarding network.
 11. The method according to claim 1, wherein sending the data packet is performed using a proximity interface supporting direct data communication between the communication device and an SE issuer.
 12. A method for preparing post issuance operation on a secure element (SE) controlled by a SE controlling party to a communication device, which method comprises the steps of: receiving an initial data packet from the communication device to which the SE is connected, the data packet comprising data suitable for identification of the SE and data for contacting the SE controlling party, processing the initial data packet received from the communication device, including determining from the initial data packet contact information of the SE controlling party, creating from the initial data packet a position request data packet comprising data suitable for the identification of the SE and comprising the requested information, and sending the position request data packet to an address defined by the contact data of the SE controlling party.
 13. The method according to claim 12, wherein the data for contacting the SE controlling party comprises a pointer to a remote database containing direct contact address of the SE controlling party.
 14. The method according to claim 12, wherein the data for contacting the SE controlling party comprises contact information of an agent of an SE issuer.
 15. The method according to claim 12, further including in the position request data packet data relating to size of a security domain to be created and data suitable for the identification of the external party and its application.
 16. The method according to claim 12, wherein the position request data packet is sent over an information forwarding network.
 17. The method according to claim 1, wherein a requested operation on the secure element is performed using an interface supporting direct data communication between the communication device and the SE controlling party.
 18. A communication device for reading a secure element (SE), programmed to: collect data stored on the SE comprising data suitable for identification of the SE and data for contacting a party controlling the SE, create a data packet comprising at least data suitable for identification of the SE and data for contacting the party controlling the SE, and send the data packet to an addressee chosen from a group consisting of an external party, an agent of the external party and the party controlling the SE.
 19. The communication device according to claim 18, wherein the agent of the external party is a trusted service manager and the party controlling the SE includes an SE issuer and a trusted service manager of the SE issuer.
 20. The communication device according to claim 18, wherein the communication device is selected from a group consisting of mobile handsets, personal computers, laptops, netbooks, notepads, handheld computers and stationary service terminals.
 21. A software application configured for installation on a communication device connectable to a secure element (SE) and adapted for: collecting from the SE data suitable for identification of the SE and data for contacting an SE controlling party, creating a data packet comprising at least data suitable for identification of the SE and data for contacting the SE controlling party, and sending the data packet to an addressee chosen from the group consisting of an external party, an agent of the external party, and the SE controlling party. 